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An inverted continental Moho and serpentinization of the forearc mantle M.G. Bostock, R.D. Hyndman, S. Rondenay, and S.M. Peacock Presented by: Lauren.

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Presentation on theme: "An inverted continental Moho and serpentinization of the forearc mantle M.G. Bostock, R.D. Hyndman, S. Rondenay, and S.M. Peacock Presented by: Lauren."— Presentation transcript:

1 An inverted continental Moho and serpentinization of the forearc mantle M.G. Bostock, R.D. Hyndman, S. Rondenay, and S.M. Peacock Presented by: Lauren Mattatall March 26, 2007

2 ► To explore structure of the mantle wedge in the southern Cascadia subduction zone (CSZ) ► To understand the observed variations in velocity structure in the forearc region

3 ► Relief map of the CSZ  White squares represent broadband stations ► Collected data from a dense broadband array of 69 stations across Central Oregon  high-quality P-wave seismograms from 31 events Bostock et al., 2002

4 Applied formal, multichannel inversions of: 1) Applied formal, multichannel inversions of: -forward scattered P to S wave conversions -back-scattered waves caused by free surface reflections 2) Plotted perturbations in velocity structure Bostock et al., 2002

5 3) Plotted a thermal model for Central Oregon -based on teleseismic profile, heat flow, and other geophysical data ► Note that the temperatures in the forearc are 400°-600° (200°-400° colder than arc temperatures)

6 ► Sharp increase in dip angle (from ~10° to ~30°) argues for eclogitization of the slab ► Eclogitization implies hydration and serpentinization of the forearc ► Thermal model temperatures are within the range that serpentine minerals are thought to be stable ► With a high enough % composition, serpentinization of the forearc would significantly reduce S-wave velocities Bostock et al., 2002

7 ► As presence of serpentinite increases, S-wave velocities decrease ► Observed S-wave velocities in the forearc indicate a possible composition of serpentinite as high as 50-60% Bostock et al., 2002

8

9 ► Serpentine and it’s alteration products are though to exhibit stable sliding properties and will impede rupture into the forearc mantle ► Mantle flow into the wedge may be modified by the presence of the serpentinized forearc mantle  The weak rheology and positive buoyancy will cause isolation from the mantle-wedge corner flow system

10 ► To what depth are the perturbation plots reliable? ► Are there other possible explanations for such a decreased velocity within the forearc?

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